The unconstrained minimization of a sufficiently smooth objective function f(x) is considered, for which derivatives up to order p, p≥2, are assumed to be available. An adaptive regularization algorithm is proposed that uses Taylor models of the objective of order p and that is guaranteed to find a first- and second-order critical point in at most O(max(ϵ1−pp+1,ϵ2−p−1p+1)) function and derivatives evaluations, where ϵ1 and ϵ2>0 are prescribed first- and second-order optimality tolerances. Our approach extends the method in Birgin et al. (2016) to finding second-order critical points, and establishes the novel complexity bound for second-order criticality under identical problem assumptions as for first-order, namely, that the p-th derivative tensor is Lipschitz continuous and that f(x) is bounded from below. The evaluation-complexity bound for second-order criticality improves on all such known existing results.
@article{arxiv.1708.04044,
title = {Improved second-order evaluation complexity for unconstrained nonlinear optimization using high-order regularized models},
author = {Coralia Cartis and Nicholas I. M. Gould and Philippe L. Toint},
journal= {arXiv preprint arXiv:1708.04044},
year = {2021}
}